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Siberian jay

April 13, 2024

The Siberian jay (Perisoreus infaustus) is a small jay with a widespread distribution within the coniferous forests in North Eurasia. It has grey-brown plumage with a darker brown crown and a paler throat. It is rusty-red in a panel near the wing-bend, on the undertail coverts and on the sides of the tail. The sexes are similar. Although its habitat is being fragmented, it is a common bird with a very wide range so the International Union for Conservation of Nature has assessed its conservation status as being of "least concern".

Siberian jay
Near Kittilä, Finland
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Passeriformes
Family: Corvidae
Genus: Perisoreus
Species:
P. infaustus
Binomial name
Perisoreus infaustus
Current approximate range according to the IUCN
Synonyms[2]
  • Corvus infaustus Linnaeus, 1758
  • Lanius infaustus Linnaeus, 1766

Taxonomy and systematics edit

The Siberian jay was formally described by the Swedish naturalist Carl Linnaeus in 1758 in the tenth edition of his Systema Naturae under the binomial name Corvus infaustus.[3] Linnaeus specified the location as "Europae alpinis sylvis" but the type location was restricted to Sweden by Ernst Hartert in 1903.[4][5] The specific epithet infaustus is Latin meaning "unlucky" or "unfortunate" as Siberian jays were formerly considered a bad omen.[6] The Siberian jay is now placed together with the Canada jay and the Sichuan jay in the genus Perisoreus that was introduced in 1831 by Charles Lucien Bonaparte.[7][8]

Five subspecies are recognised:[8]

  • P. i. infaustus (Linnaeus, 1758) – Scandinavia to west Siberia (includes ruthenus)
  • P. i. rogosowi Sushkin & Stegmann, 1929 – northeast European Russia to northcentral Siberia (includes ostjakorum)
  • P. i. opicus Bangs, 1913 – east Kazakhstan, northwest China and south central Siberia
  • P. i. sibericus (Boddaert, 1783) – central Siberia and north Mongolia (includes yakutensis and tkachenkoi)
  • P. i. maritimus Buturlin, 1915 – southeast Siberia and northeast China

The Siberian jay differs from the other two species in its group-living behaviours. Unlike the other two species, where group individuals unrelated to breeding parents may help provision the young,[9] the group individuals accompanying a breeding pair of Siberian jays do not help raise the offspring.[10] The lack of extra-parental care within the groups may be due to historic selection against cooperative breeding in the Siberian jay;[11] probably as an anti-predator strategy to avoid predator attention.[9]

With the colonisation of coniferous forests in Scandinavia just after the last ice age, the Siberian jay probably expanded its range from east to west in response to the newly formed suitable habitat resulting from climatic warming.[12]

Description edit

 
In a spruce forest near Evenstad, Norway

The Siberian jay is the smallest of the western Palearctic corvids, weighing 75 to 90 g (2.6 to 3.2 oz)[13] and measuring about 30 centimetres (12 inches) in length.[14] The adult plumage is greyish brown, with a dark brown head, paler forehead and buff breast. The rump is yellowish and the chin and throat are grey. There is also rufous streaking on the outer feathers, and the bill and legs are black.[15] Their overall colouration is fairly inconspicuous to visually conceal them from predators within their forest habitat.[16] The plumage is also very soft and downy for insulation against extreme cold in winter.[15] There is one moult per year, which lasts from mid-June to mid-September.[15] The longest recorded lifetime is 13 years 4 months for a bird ringed in Finland,[17] although the average lifespan has been reported as 7.1 years.[1]

Siberian jays appear to be specially adapted to navigate in flight through dense forest despite being rather cumbersome flyers across open terrain. This may explain their vulnerability to predation by raptors outside forests.[18]

Voice edit

The Siberian jay is mostly silent but can utter a loud screech resembling that of a buzzard (Buteo spp.). The song, which is performed by both sexes, mainly during the breeding season and heard only from a short distance, comprises a wide repertoire of sounds. These range from sequences of separate soft and harsh notes to bouts of whistling, creaking and trilling, sometimes incorporating mimicked song of other birds.[16][15] Siberian jays also engage in nepotistic alarming calling, which may serve to warn conspecifics of an approaching predator.[19] Warning calls have been shown experimentally to decrease reaction time in response in an approaching predator and improve survival within non-breeding individuals.[19] However, females seem more able than males to differentiate between kin and non-kin.[20] Alongside direct warning to family group members, nepotistic alarm calling by a breeding female may also function to divert predator attention away from her offspring.[20]

Distribution and habitat edit

The Siberian jay is resident in the northern boreal spruce, pine, cedar and larch forests stretching from Scandinavia to northern Russia and Siberia.[16] The species has an extensive range estimated at 19,300,000 square kilometres (7,500,000 square miles)[1] and is native to Norway, Sweden, Finland, Russia, Mongolia, Kazakhstan and China.[1] It is vagrant in Belarus, Estonia, Latvia, Poland, Slovakia and Ukraine.[1] Despite being largely sedentary, some southward movement may occur in winter by individuals in the east part of the range.[21]

This jay prefers dense, mature forest habitat with closed canopy within lowlands and foothills.[21] Spruce forest is the preferred foraging and nesting habitat because the denser foliage of spruce than other local conifers better conceals the bird from the watchful eyes of predators.[22] Indeed, high breeding success has been linked to high foliage density, since eggs and nestlings are better hidden from view and so less likely to attract predators.[13] Additionally, the benefit of increased predator evasion through more hiding space would probably outweigh the cost of making predators more difficult to see by the jays within the dense foliage.[23] The Siberian jay is notably selective in its choice of territory, with a typical territory comprising old dense spruce swamp with ample vegetation cover.[22] Territories also tend to be structurally diverse, comprising variably aged scrub, groves and flood meadows; so that active territories may be regarded as an indicator of high ecological diversity within the forest.[18]

Behaviour and ecology edit

The species has a complex and unusual social structure.[10] Siberian jays live in small flocks of 2–7 individuals, with the dominant breeding pair at the centre of the group;[24][25] alongside retained multigenerational offspring and unrelated immigrants.[10][25] Within a group, there is a dominance hierarchy; whereby males are dominant over females and breeders are dominant over non-breeders; with some male non-breeders being dominant over female breeders.[10] Flock composition varies, with some comprising only family members, families associated with nonrelated immigrants, and others containing only nonrelated individuals.[24] Immigrated unrelated individuals can be tolerated within the territory outside nesting areas.[15]

Siberian jays are aggressive to non-related intruders on their territory. Two different aggressive responses from territory holders within feeding grounds have been observed: (1) the intruder is approached and forced away, (2) or is chased in flight; although the latter behaviour is more costly to the aggressor.[10] Although breeders are considerably more aggressive toward immigrants than retained offspring,[10] aggressive responses appear to be modified by social dominance within groups.[25] For example, females have been found to receive significantly more aggression than males because males show more resistance on account of their higher social ranking, therefore resulting in a higher energy cost on the part of the aggressor.[25] Siberian jays also appear to recognise their own young through associative learning as opposed to genetic cues, as shown by experiments in which Siberian jays did not differentiate between own and fostered offspring.[25]

Breeding edit

 
Eggs in the Museum Wiesbaden

Siberian Jays are strictly monogamous, with an established pair staying together and holding the same territory for life.[16] Mate guarding in both sexes has been observed, whereby males and females become increasingly aggressive toward same-sex conspecifics.[26] This may prevent extra-pair mating opportunities for the partner and thereby preserve inclusive fitness for both pair members.[26] The size of the territory is 1 to 4 km2 (0.39 to 1.54 sq mi), which is slightly enlarged in autumn and winter.[16][27] Although territories are firmly established, the jays can move to a neighbouring site if this is a better quality habitat where breeding success will be higher.[28][13] Widowed individuals have been observed to establish new pair bonds.[27]

The nest is situated in a pine or spruce tree 4–6 m (13–20 ft) above ground[16] within dense foliage for optimal concealment from nest predators.[29] The nest comprises a loose cup of dry twigs broken off trees by the jays[16] and is thickly lined with beard lichen moss, down feathers, cobwebs, reindeer fur and wasp nest fragments; which serves as necessary insulation against the extreme winter cold.[15] Nest material is hoarded in winter long before building takes place.[16] Nest building proper begins in late March and lasts for about three weeks.[15] Both partners collect nest material; but only the female builds the nest.[16]

The eggs are pale green, blue or grey and spotted with grey and brown. The average size is 31.6 mm × 22.9 mm (1.24 in × 0.90 in).[30] They are laid 31 March – 22 April, with a variable clutch size of 1–5 and an incubation period of about 19 days.[15][29] The eggs are incubated entirely by the female,[29] whilst the male provides all the food for the brooding female and the chicks.[31] The Siberian jay is single brooded and does not relay in a breeding season even after nest failure, but will wait until next year.[29] A new nest is also built for every breeding attempt.[29] Newly hatched young are almost bare and are closely covered by the female. Juveniles look similar to adults, but have paler heads.[15]

A high proportion of the diet of the young comprises insect larvae, which is collected by the male and stored in his oesophagus until he returns to the nest to regurgitate it to feed to the young.[15] In the first week of brooding, the male provides the female and young with all their food, and the female takes an increasing share of the work thereafter.[16]

The young fledge in mid-May to early June and leave the nest around this time, 18–24 days after the first chick has hatched;[15][27][31] although they usually hide within tree branches on the territory until they are able to properly fly.[18] Parents continue to feed the young for about three weeks after fledging, with all of them remaining in a family group throughout summer, autumn and winter.[16] Most mature young disperse from the natal territory in their first summer 4–8 weeks after fledging to join new groups which are usually situated more than four territories away from the natal one.[32] These early dispersers are generally subordinates which have been out-competed and displaced by one or a few socially dominant offspring that are retained.[10][13] If offspring have not yet dispersed by the time they are eight weeks old, they usually remain in the natal territory at least through the first winter.[13] The retained, socially dominant offspring remaining on the natal territory may wait for up to five years before dispersing, whenever a suitable breeding opportunity arises.[26] Retained offspring can also claim their natal territory, but this happens only in the rare event that both parents disappear from the territory within a relatively short time.[13] Offspring may inherit the new territory to which they disperse and at which they breed.[13] However, if there are no vacant territories to occupy, juveniles can join a different family group to gain feeding advantages and may even attempt to establish their own territory at the age of 2–3 years.[18]

Retention of some offspring in the natal territory after fledging is probably best explained by the nepotism (favoritism granted by individuals to related individuals of the same species) which parents show towards them.[33] Parents provide retained offspring with reliable access to resources and antipredator protection,[23] thereby imparting to them a survival advantage[24][13] (in turn with an inclusive fitness advantage to the parents). Although delayed dispersal of offspring may be explained by “queueing” for available high-quality territories for the offspring to occupy,[28] the influence of nepotism has been shown experimentally. In removal experiments in which a father alpha male in a group was replaced with a new male unrelated to the offspring, the offspring were more likely to disperse prematurely; probably because the new male did not impart the same nepotistic advantages to the now unrelated young.[33] Although retained offspring may incur an initial cost of postponing breeding, this may be offset by enhanced breeding success later in life as a result of resource advantages gained from nepotistic parents;[13] and late dispersers have been found to have higher lifetime reproductive success than early dispersers.[34]

At least one offspring usually remains with the parents after successful reproduction and regularly accompanies the pair for at least a year before dispersing;[35] although some retained offspring may delay their dispersal for up to five years.[28][32] These are the dominant offspring which out-compete and expel their subordinate siblings.[24] The dispersed subordinate individuals (which disperse in their first summer) settle as non-breeding immigrants in other existing flocks[33][32][36] and tend to disperse much further than their dominant siblings, which more often move straight into a breeding position in a new territory.[36] Unusually for a gregarious corvid species, members in a group of Siberian jays do not help the parents raise younger siblings in future cohorts (i.e., there is no cooperative breeding) and so offspring retention is not explained by cooperative breeding.[10] Groups also stay together outside the breeding season, which is another unusual phenomenon.[28][27]

Feeding edit

The Siberian Jay is omnivorous, feeding mainly on berries, seeds, insects and spiders.[37] Flocks will also feed on large carcasses killed by mammalian predators such as wolves and wolverines.[13] Other occasional food items include eggs of small birds, tit nestlings, snails, slugs, small mammals and lizards.[16][18] In autumn and winter, berries (especially bilberries and cowberries) are typically collected and stored behind loose bark or in hanging beard lichen and between forked twigs.[16][15] Siberian jays distribute many different hidden food caches over a large area and are therefore known as scatter hoarders.[35] However, unlike in other corvids, this hidden food stash is not purposefully shared with siblings to increase inclusive fitness but is consumed by the hoarder or a pilferer for selfish use.[35] These food caches are critical to this species' winter survival since foraging time is greatly restricted by the few hours of daylight.[14] To securely store food, Siberian jays have developed special saliva glands which they use to form sticky food clumps which they can adhere to beard moss or holes in tree bark where they are readily accessible throughout the winter.[18] Because of their reliance on food stores during winter, these birds are territorial and hold food reserves scattered around the territory, especially near to the nest.[18]

When foraging, Siberian jays often stay within the closed-canopy forest to avoid visual detection by predators,[14] although they may occasionally forage for insects in wet, tussock-strewn open areas.[16] They forage in flocks comprising 3–5 individuals within their large territory.[35] Especially in winter, Siberian jays will also venture into increasingly open areas to take and store small rodents for food when the latter are abundant.[14]

Threats edit

Birds of prey, especially hawks such the goshawk and sparrowhawk, are the main predators of Siberian jays.[24][14] Most Siberian jay predators detect prey visually, so that the combination of ample forest foliage cover with the jays' cryptic colouration and secretive nesting helps render the jays inconspicuous to potential predators.[38] Predators of this species' eggs and young include squirrels, ravens, hooded crows, magpies and Eurasian jays. The nest is constructed within the dense foliage to avoid attracting the attention of predators. Females also appear to lay smaller clutches under higher predation pressure, which may help to avoid attracting predator attention to the nest since fewer visits to the nest by the parent are necessary.[29] Further, in higher cover nests, chicks are fed by the parent more evenly than in exposed nests more detectable by predators; so that chicks raised in well-concealed nests are expected to have better growth.[29]

The European expanse of the population is threatened by habitat degradation through the encroachments of forestry, road building, settlements and agriculture.[39] Modern European forestry practices in particular may be lessening the quality of breeding habitats for the Siberian jay by depriving the birds of sufficient foliage cover.[29] This may occur through forest thinning, whereby lower-quality trees are regularly removed from forest stands. Excessive clearcutting has been linked with increased territory abandonment by Siberian jays, leading to strong decreases in the species' breeding success in affected areas.[40] Another practice which may threaten the Siberian jay has been the large-scale removal of stands of native spruce to be replaced with pine, potentially leading to loss of sufficient visual cover of nesting activity from predators with removal of spruce.[22] In Finland, spruce has also been declining faster than other forest types and loss and fragmentation of spruce forests through forestry has been linked with population declines here.[41] Anthropogenic habitat loss may be interacting with natural threats from predators. The Siberian jay population has declined more than can be explained by anthropogenic forest clearance alone,[42] which may be attributable to increased nest exposure to avian predators and other human activities favouring these predatory species.[38] Human activity may also favour nest predators such as Eurasian jays through supplemental feeding and refuse dumpling, thereby compounding the predation pressure on Siberian jays through visual exposure to predators.[38] Finally, destruction by felling of winter food storages in trees near territories during winter may also destroy winter food caches.[18]

Alongside increased predator attention, the open land exposed as a result of forest habitat fragmentation also presents an apparently large dispersal barrier which the jays may find difficult to cross given their apparent cumbersomeness at traversing open land.[18] Siberian jays also appear unable to evolve fast enough to adapt to these anthropogenic habitat and predator population changes.[38] Because of this species' sedentary habit, there appear to be several genetically isolated subpopulations.[12] Given this jay's high site fidelity, gene flow between subpopulations may have been low even before onset of modern forestry practices which have created the strong dispersal barriers.[12]

In culture and relationship with humans edit

Siberian jays are reported to be fearless in human company, and, with repeated provision of food by humans in the same place, may become tame enough to take food from the hand.[16] This was especially the case when forestry workers used to regularly leave patches of food scraps in the forest or around campfires for the jays to take.[16] The Siberian jay has now gained flagship status as a conservation concern both because of threats from modern forestry and because active territories are considered a sign of high-quality biodiverse forest.[18]

Status edit

The Siberian jay is evaluated as Least Concern by the IUCN because of the species’ exceptionally large range.[1] Although the world population is declining, the magnitude of this drop is not deemed to be sufficiently large to render the species Vulnerable.[1] The world population is very large and estimated at 4–8 million mature individuals.[1] Population declines have been reported to be strongest in the southernmost part of the range.[1]

References edit

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  2. ^ "Siberian Jay Perisoreus infaustus (Linnaeus, 1758)". Avibase. Denis Lepage. Retrieved 2 July 2017.
  3. ^ Linnaeus, Carl (1758). Systema Naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis (in Latin). Vol. 1 (10th ed.). Holmiae (Stockholm): Laurentii Salvii. p. 107.
  4. ^ Mayr, Ernst; Greenway, James C. Jr, eds. (1962). Check-List of Birds of the World. Vol. 15. Cambridge, Massachusetts: Museum of Comparative Zoology. p. 238.
  5. ^ Hartert, Ernst (1903). Die Vögel der paläarktischen Fauna (in German). Vol. 1. Berlin: R. Friedländer und Sohn. p. 34.
  6. ^ Jobling, James A. (2010). The Helm Dictionary of Scientific Bird Names. London: Christopher Helm. p. 205. ISBN 978-1-4081-2501-4.
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  8. ^ a b Gill, Frank; Donsker, David; Rasmussen, Pamela, eds. (January 2021). "Crows, mudnesters, birds-of-paradise". IOC World Bird List Version 11.1. International Ornithologists' Union. Retrieved 16 May 2021.
  9. ^ a b Jing, Y.; Fang, Y.; Strickland, D.; Lu, N.; Sun, Y.-H. (2009). "Alloparenting in the rare Sichuan Jay (Perisoreus internigrans)". The Condor. 111 (4): 662–667. doi:10.1525/cond.2009.080114.
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  13. ^ a b c d e f g h i j Ekman, Jan; Griesser, Michael (2016). "Siberian jays: delayed dispersal in the absence of cooperative breeding". In Walt Koenig; Janis L Dickinson (eds.). Cooperative breeding in vertebrates: studies of ecology, evolution, and behavior. Cambridge University Press. pp. 6–18. doi:10.1017/CBO9781107338357.002. ISBN 9781107043435.
  14. ^ a b c d e Hogstad, Olaf (2016). "Hunting strategies by Siberian jays Perisoreus infaustus on wintering small rodents". Ornis Norvegica. 39: 25–28. doi:10.15845/on.v39i0.1031.
  15. ^ a b c d e f g h i j k l Coombs, Franklin (1978). The Crows : a Study of the Corvids of Europe. London: B.T. Batsford. OCLC 610890402.
  16. ^ a b c d e f g h i j k l m n o p Blomgren, Arne (1971). "Studies of less familiar birds: 162 Siberian Jay" (PDF). British Birds. 64: 25–28.
  17. ^ "European Longevity Records". Euring. Retrieved 17 May 2021.
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  19. ^ a b Griesser, Michael (2013). "Do warning calls boost survival of signal recipients? Evidence from a field experiment in a group-living bird species". Frontiers in Zoology. 10 (1): 49. doi:10.1186/1742-9994-10-49. PMC 3751016. PMID 23941356.
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  22. ^ a b c Edenius, Lars; Meyer, Carsten (2002). "Activity budgets and microhabitat use in the Siberian Jay Perisoreus infaustus in managed and unmanaged forest" (PDF). Ornis Fennica. 79: 26–33.
  23. ^ a b Nystrand, Magdalena (2006). "Influence of age, kinship, and large-scale habitat quality on local foraging choices of Siberian jays". Behavioral Ecology. 17 (3): 503–509. doi:10.1093/beheco/arj055.
  24. ^ a b c d e Griesser, Michael (2003). "Nepotistic vigilance behavior in Siberian jay parents". Behavioral Ecology. 14 (2): 246–250. doi:10.1093/beheco/14.2.246.
  25. ^ a b c d e Griesser, M.; Halvarsson, P.; Drobniak, S.M.; Vilà, C. (2015). "Fine-scale kin recognition in the absence of social familiarity in the Siberian jay, a monogamous bird species" (PDF). Molecular Ecology. 24 (22): 5726–5738. doi:10.1111/mec.13420. PMID 26460512.
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  27. ^ a b c d Lillandt, B.-G.; Bensch, S.; von Schantz, T. (2003). "Family structure in the Siberian jay as revealed by microsatellite analyses". The Condor. 105 (3): 505–514. doi:10.1093/condor/105.3.505.
  28. ^ a b c d Ekman, J.; Eggers, S.; Griesser, M.; Tegelström, H. (2001). "Queuing for preferred territories: delayed dispersal of Siberian jays". Journal of Animal Ecology. 70 (2): 317–324. doi:10.1111/j.1365-2656.2001.00490.x.
  29. ^ a b c d e f g h Eggers, S.; Griesser, M.; Nystrand, M.; Ekman, J. (2006). "Predation risk induces changes in nest-site selection and clutch size in the Siberian jay". Proceedings of the Royal Society B: Biological Sciences. 273 (1587): 701–706. doi:10.1098/rspb.2005.3373. PMC 1560074. PMID 16608689.
  30. ^ Harrison C. 1975. A Field Guide to the Nests, Eggs and Nestlings of British and European Birds. London
  31. ^ a b Eggers S. 2002. Behaviour and life-history responses to chick provisioning under the risk of nest predation. PhD dissertation, Uppsala University.
  32. ^ a b c Griesser, M.; Nystrand, M.; Eggers, S.; Ekman, J. (2008). "Social constraints limit dispersal and settlement decisions in a group-living bird species". Behavioral Ecology. 19 (2): 317–324. doi:10.1093/beheco/arm131.
  33. ^ a b c Ekman, Jan; Griesser, Michael (2002). "Why offspring delay dispersal: experimental evidence for a role of parental tolerance". Proceedings of the Royal Society of London. Series B: Biological Sciences. 269 (1501): 1709–1713. doi:10.1098/rspb.2002.2082. PMC 1691083. PMID 12204132.
  34. ^ Ekman, J.; Bylin, A.; Tegelstrom, H. (1999). "Increased lifetime reproductive success for Siberian Jay (Perisoreus infaustus) males with delayed dispersal". Proceedings of the Royal Society B. 266 (1422): 911–915. doi:10.1098/rspb.1999.0723. PMC 1689928.
  35. ^ a b c d Ekman, J.; Brodin, A.; Bylin, A.; Sklepkovych, B. (1996). "Selfish long-term benefits of hoarding in the Siberian jay". Behavioral Ecology. 7 (2): 140–144. doi:10.1093/beheco/7.2.140.
  36. ^ a b Griesser, M.; Halvarsson, P.; Sahlman, T.; Ekman, J. (2014). "What are the strengths and limitations of direct and indirect assessment of dispersal? Insights from a long-term field study in a group-living bird species" (PDF). Behavioral Ecology and Sociobiology. 68 (3): 485–497. doi:10.1007/s00265-013-1663-x.
  37. ^ Virkkala, Raimo (1988). "Foraging niches of foliage-gleaning birds in the northernmost taiga in Finland" (PDF). Ornis Fennica. 65: 104–113.
  38. ^ a b c d Eggers, S.; Griesser, M.; Andersson, T.; Ekman, J. (2005). "Nest predation and habitat change interact to influence Siberian jay numbers". Oikos. 111 (1): 150–158. doi:10.1111/j.0030-1299.2005.13802.x.
  39. ^ Hagemeijer, E.J.M.; Blair, M.J., eds. (1997). The EBCC Atlas of European breeding Birds: their Distribution and Abundance. London: T. and A. D. Poyser. ISBN 978-0-85661-091-2.
  40. ^ Griesser, M.; Nystrand, M.; Eggers, S.; Ekman, J. (2007). "Impact of forestry practices on fitness correlates and population productivity in an open-nesting bird species" (PDF). Conservation Biology. 21 (3): 767–774. doi:10.1111/j.1523-1739.2007.00675.x. PMID 17531054.
  41. ^ Muukkonen, P.; Angervuori, A.; Virtanen, T.; Kuparinen, A.; Merila, J. (2012). "Loss and fragmentation of Siberian jay (Perisoreus infaustus) habitats" (PDF). Boreal Environment Research. 17: 59–71.
  42. ^ Helle, Pekka; Järvinen, Olli (1986). "Population trends of North Finnish land birds in relation to their habitat selection and changes in forest structure". Oikos. 46 (1): 107–115. doi:10.2307/3565386. JSTOR 3565386.

External links edit

  • Audio recordings from Xeno-canto
  • An info-card on the Siberian Jay — at Birdlife.org

April 13, 2024
siberian, perisoreus, infaustus, small, with, widespread, distribution, within, coniferous, forests, north, eurasia, grey, brown, plumage, with, darker, brown, crown, paler, throat, rusty, panel, near, wing, bend, undertail, coverts, sides, tail, sexes, simila. The Siberian jay Perisoreus infaustus is a small jay with a widespread distribution within the coniferous forests in North Eurasia It has grey brown plumage with a darker brown crown and a paler throat It is rusty red in a panel near the wing bend on the undertail coverts and on the sides of the tail The sexes are similar Although its habitat is being fragmented it is a common bird with a very wide range so the International Union for Conservation of Nature has assessed its conservation status as being of least concern Siberian jayNear Kittila FinlandConservation statusLeast Concern IUCN 3 1 1 Scientific classificationDomain EukaryotaKingdom AnimaliaPhylum ChordataClass AvesOrder PasseriformesFamily CorvidaeGenus PerisoreusSpecies P infaustusBinomial namePerisoreus infaustus Linnaeus 1758 Current approximate range according to the IUCNSynonyms 2 Corvus infaustus Linnaeus 1758 Lanius infaustus Linnaeus 1766 Contents 1 Taxonomy and systematics 2 Description 2 1 Voice 3 Distribution and habitat 4 Behaviour and ecology 4 1 Breeding 4 2 Feeding 5 Threats 6 In culture and relationship with humans 7 Status 8 References 9 External linksTaxonomy and systematics editThe Siberian jay was formally described by the Swedish naturalist Carl Linnaeus in 1758 in the tenth edition of his Systema Naturae under the binomial name Corvus infaustus 3 Linnaeus specified the location as Europae alpinis sylvis but the type location was restricted to Sweden by Ernst Hartert in 1903 4 5 The specific epithet infaustus is Latin meaning unlucky or unfortunate as Siberian jays were formerly considered a bad omen 6 The Siberian jay is now placed together with the Canada jay and the Sichuan jay in the genus Perisoreus that was introduced in 1831 by Charles Lucien Bonaparte 7 8 Five subspecies are recognised 8 P i infaustus Linnaeus 1758 Scandinavia to west Siberia includes ruthenus P i rogosowi Sushkin amp Stegmann 1929 northeast European Russia to northcentral Siberia includes ostjakorum P i opicus Bangs 1913 east Kazakhstan northwest China and south central Siberia P i sibericus Boddaert 1783 central Siberia and north Mongolia includes yakutensis and tkachenkoi P i maritimus Buturlin 1915 southeast Siberia and northeast ChinaThe Siberian jay differs from the other two species in its group living behaviours Unlike the other two species where group individuals unrelated to breeding parents may help provision the young 9 the group individuals accompanying a breeding pair of Siberian jays do not help raise the offspring 10 The lack of extra parental care within the groups may be due to historic selection against cooperative breeding in the Siberian jay 11 probably as an anti predator strategy to avoid predator attention 9 With the colonisation of coniferous forests in Scandinavia just after the last ice age the Siberian jay probably expanded its range from east to west in response to the newly formed suitable habitat resulting from climatic warming 12 Description edit nbsp In a spruce forest near Evenstad NorwayThe Siberian jay is the smallest of the western Palearctic corvids weighing 75 to 90 g 2 6 to 3 2 oz 13 and measuring about 30 centimetres 12 inches in length 14 The adult plumage is greyish brown with a dark brown head paler forehead and buff breast The rump is yellowish and the chin and throat are grey There is also rufous streaking on the outer feathers and the bill and legs are black 15 Their overall colouration is fairly inconspicuous to visually conceal them from predators within their forest habitat 16 The plumage is also very soft and downy for insulation against extreme cold in winter 15 There is one moult per year which lasts from mid June to mid September 15 The longest recorded lifetime is 13 years 4 months for a bird ringed in Finland 17 although the average lifespan has been reported as 7 1 years 1 Siberian jays appear to be specially adapted to navigate in flight through dense forest despite being rather cumbersome flyers across open terrain This may explain their vulnerability to predation by raptors outside forests 18 Voice edit The Siberian jay is mostly silent but can utter a loud screech resembling that of a buzzard Buteo spp The song which is performed by both sexes mainly during the breeding season and heard only from a short distance comprises a wide repertoire of sounds These range from sequences of separate soft and harsh notes to bouts of whistling creaking and trilling sometimes incorporating mimicked song of other birds 16 15 Siberian jays also engage in nepotistic alarming calling which may serve to warn conspecifics of an approaching predator 19 Warning calls have been shown experimentally to decrease reaction time in response in an approaching predator and improve survival within non breeding individuals 19 However females seem more able than males to differentiate between kin and non kin 20 Alongside direct warning to family group members nepotistic alarm calling by a breeding female may also function to divert predator attention away from her offspring 20 Distribution and habitat editThe Siberian jay is resident in the northern boreal spruce pine cedar and larch forests stretching from Scandinavia to northern Russia and Siberia 16 The species has an extensive range estimated at 19 300 000 square kilometres 7 500 000 square miles 1 and is native to Norway Sweden Finland Russia Mongolia Kazakhstan and China 1 It is vagrant in Belarus Estonia Latvia Poland Slovakia and Ukraine 1 Despite being largely sedentary some southward movement may occur in winter by individuals in the east part of the range 21 This jay prefers dense mature forest habitat with closed canopy within lowlands and foothills 21 Spruce forest is the preferred foraging and nesting habitat because the denser foliage of spruce than other local conifers better conceals the bird from the watchful eyes of predators 22 Indeed high breeding success has been linked to high foliage density since eggs and nestlings are better hidden from view and so less likely to attract predators 13 Additionally the benefit of increased predator evasion through more hiding space would probably outweigh the cost of making predators more difficult to see by the jays within the dense foliage 23 The Siberian jay is notably selective in its choice of territory with a typical territory comprising old dense spruce swamp with ample vegetation cover 22 Territories also tend to be structurally diverse comprising variably aged scrub groves and flood meadows so that active territories may be regarded as an indicator of high ecological diversity within the forest 18 Behaviour and ecology editThe species has a complex and unusual social structure 10 Siberian jays live in small flocks of 2 7 individuals with the dominant breeding pair at the centre of the group 24 25 alongside retained multigenerational offspring and unrelated immigrants 10 25 Within a group there is a dominance hierarchy whereby males are dominant over females and breeders are dominant over non breeders with some male non breeders being dominant over female breeders 10 Flock composition varies with some comprising only family members families associated with nonrelated immigrants and others containing only nonrelated individuals 24 Immigrated unrelated individuals can be tolerated within the territory outside nesting areas 15 Siberian jays are aggressive to non related intruders on their territory Two different aggressive responses from territory holders within feeding grounds have been observed 1 the intruder is approached and forced away 2 or is chased in flight although the latter behaviour is more costly to the aggressor 10 Although breeders are considerably more aggressive toward immigrants than retained offspring 10 aggressive responses appear to be modified by social dominance within groups 25 For example females have been found to receive significantly more aggression than males because males show more resistance on account of their higher social ranking therefore resulting in a higher energy cost on the part of the aggressor 25 Siberian jays also appear to recognise their own young through associative learning as opposed to genetic cues as shown by experiments in which Siberian jays did not differentiate between own and fostered offspring 25 Breeding edit nbsp Eggs in the Museum WiesbadenSiberian Jays are strictly monogamous with an established pair staying together and holding the same territory for life 16 Mate guarding in both sexes has been observed whereby males and females become increasingly aggressive toward same sex conspecifics 26 This may prevent extra pair mating opportunities for the partner and thereby preserve inclusive fitness for both pair members 26 The size of the territory is 1 to 4 km2 0 39 to 1 54 sq mi which is slightly enlarged in autumn and winter 16 27 Although territories are firmly established the jays can move to a neighbouring site if this is a better quality habitat where breeding success will be higher 28 13 Widowed individuals have been observed to establish new pair bonds 27 The nest is situated in a pine or spruce tree 4 6 m 13 20 ft above ground 16 within dense foliage for optimal concealment from nest predators 29 The nest comprises a loose cup of dry twigs broken off trees by the jays 16 and is thickly lined with beard lichen moss down feathers cobwebs reindeer fur and wasp nest fragments which serves as necessary insulation against the extreme winter cold 15 Nest material is hoarded in winter long before building takes place 16 Nest building proper begins in late March and lasts for about three weeks 15 Both partners collect nest material but only the female builds the nest 16 The eggs are pale green blue or grey and spotted with grey and brown The average size is 31 6 mm 22 9 mm 1 24 in 0 90 in 30 They are laid 31 March 22 April with a variable clutch size of 1 5 and an incubation period of about 19 days 15 29 The eggs are incubated entirely by the female 29 whilst the male provides all the food for the brooding female and the chicks 31 The Siberian jay is single brooded and does not relay in a breeding season even after nest failure but will wait until next year 29 A new nest is also built for every breeding attempt 29 Newly hatched young are almost bare and are closely covered by the female Juveniles look similar to adults but have paler heads 15 A high proportion of the diet of the young comprises insect larvae which is collected by the male and stored in his oesophagus until he returns to the nest to regurgitate it to feed to the young 15 In the first week of brooding the male provides the female and young with all their food and the female takes an increasing share of the work thereafter 16 The young fledge in mid May to early June and leave the nest around this time 18 24 days after the first chick has hatched 15 27 31 although they usually hide within tree branches on the territory until they are able to properly fly 18 Parents continue to feed the young for about three weeks after fledging with all of them remaining in a family group throughout summer autumn and winter 16 Most mature young disperse from the natal territory in their first summer 4 8 weeks after fledging to join new groups which are usually situated more than four territories away from the natal one 32 These early dispersers are generally subordinates which have been out competed and displaced by one or a few socially dominant offspring that are retained 10 13 If offspring have not yet dispersed by the time they are eight weeks old they usually remain in the natal territory at least through the first winter 13 The retained socially dominant offspring remaining on the natal territory may wait for up to five years before dispersing whenever a suitable breeding opportunity arises 26 Retained offspring can also claim their natal territory but this happens only in the rare event that both parents disappear from the territory within a relatively short time 13 Offspring may inherit the new territory to which they disperse and at which they breed 13 However if there are no vacant territories to occupy juveniles can join a different family group to gain feeding advantages and may even attempt to establish their own territory at the age of 2 3 years 18 Retention of some offspring in the natal territory after fledging is probably best explained by the nepotism favoritism granted by individuals to related individuals of the same species which parents show towards them 33 Parents provide retained offspring with reliable access to resources and antipredator protection 23 thereby imparting to them a survival advantage 24 13 in turn with an inclusive fitness advantage to the parents Although delayed dispersal of offspring may be explained by queueing for available high quality territories for the offspring to occupy 28 the influence of nepotism has been shown experimentally In removal experiments in which a father alpha male in a group was replaced with a new male unrelated to the offspring the offspring were more likely to disperse prematurely probably because the new male did not impart the same nepotistic advantages to the now unrelated young 33 Although retained offspring may incur an initial cost of postponing breeding this may be offset by enhanced breeding success later in life as a result of resource advantages gained from nepotistic parents 13 and late dispersers have been found to have higher lifetime reproductive success than early dispersers 34 At least one offspring usually remains with the parents after successful reproduction and regularly accompanies the pair for at least a year before dispersing 35 although some retained offspring may delay their dispersal for up to five years 28 32 These are the dominant offspring which out compete and expel their subordinate siblings 24 The dispersed subordinate individuals which disperse in their first summer settle as non breeding immigrants in other existing flocks 33 32 36 and tend to disperse much further than their dominant siblings which more often move straight into a breeding position in a new territory 36 Unusually for a gregarious corvid species members in a group of Siberian jays do not help the parents raise younger siblings in future cohorts i e there is no cooperative breeding and so offspring retention is not explained by cooperative breeding 10 Groups also stay together outside the breeding season which is another unusual phenomenon 28 27 Feeding edit The Siberian Jay is omnivorous feeding mainly on berries seeds insects and spiders 37 Flocks will also feed on large carcasses killed by mammalian predators such as wolves and wolverines 13 Other occasional food items include eggs of small birds tit nestlings snails slugs small mammals and lizards 16 18 In autumn and winter berries especially bilberries and cowberries are typically collected and stored behind loose bark or in hanging beard lichen and between forked twigs 16 15 Siberian jays distribute many different hidden food caches over a large area and are therefore known as scatter hoarders 35 However unlike in other corvids this hidden food stash is not purposefully shared with siblings to increase inclusive fitness but is consumed by the hoarder or a pilferer for selfish use 35 These food caches are critical to this species winter survival since foraging time is greatly restricted by the few hours of daylight 14 To securely store food Siberian jays have developed special saliva glands which they use to form sticky food clumps which they can adhere to beard moss or holes in tree bark where they are readily accessible throughout the winter 18 Because of their reliance on food stores during winter these birds are territorial and hold food reserves scattered around the territory especially near to the nest 18 When foraging Siberian jays often stay within the closed canopy forest to avoid visual detection by predators 14 although they may occasionally forage for insects in wet tussock strewn open areas 16 They forage in flocks comprising 3 5 individuals within their large territory 35 Especially in winter Siberian jays will also venture into increasingly open areas to take and store small rodents for food when the latter are abundant 14 Threats editBirds of prey especially hawks such the goshawk and sparrowhawk are the main predators of Siberian jays 24 14 Most Siberian jay predators detect prey visually so that the combination of ample forest foliage cover with the jays cryptic colouration and secretive nesting helps render the jays inconspicuous to potential predators 38 Predators of this species eggs and young include squirrels ravens hooded crows magpies and Eurasian jays The nest is constructed within the dense foliage to avoid attracting the attention of predators Females also appear to lay smaller clutches under higher predation pressure which may help to avoid attracting predator attention to the nest since fewer visits to the nest by the parent are necessary 29 Further in higher cover nests chicks are fed by the parent more evenly than in exposed nests more detectable by predators so that chicks raised in well concealed nests are expected to have better growth 29 The European expanse of the population is threatened by habitat degradation through the encroachments of forestry road building settlements and agriculture 39 Modern European forestry practices in particular may be lessening the quality of breeding habitats for the Siberian jay by depriving the birds of sufficient foliage cover 29 This may occur through forest thinning whereby lower quality trees are regularly removed from forest stands Excessive clearcutting has been linked with increased territory abandonment by Siberian jays leading to strong decreases in the species breeding success in affected areas 40 Another practice which may threaten the Siberian jay has been the large scale removal of stands of native spruce to be replaced with pine potentially leading to loss of sufficient visual cover of nesting activity from predators with removal of spruce 22 In Finland spruce has also been declining faster than other forest types and loss and fragmentation of spruce forests through forestry has been linked with population declines here 41 Anthropogenic habitat loss may be interacting with natural threats from predators The Siberian jay population has declined more than can be explained by anthropogenic forest clearance alone 42 which may be attributable to increased nest exposure to avian predators and other human activities favouring these predatory species 38 Human activity may also favour nest predators such as Eurasian jays through supplemental feeding and refuse dumpling thereby compounding the predation pressure on Siberian jays through visual exposure to predators 38 Finally destruction by felling of winter food storages in trees near territories during winter may also destroy winter food caches 18 Alongside increased predator attention the open land exposed as a result of forest habitat fragmentation also presents an apparently large dispersal barrier which the jays may find difficult to cross given their apparent cumbersomeness at traversing open land 18 Siberian jays also appear unable to evolve fast enough to adapt to these anthropogenic habitat and predator population changes 38 Because of this species sedentary habit there appear to be several genetically isolated subpopulations 12 Given this jay s high site fidelity gene flow between subpopulations may have been low even before onset of modern forestry practices which have created the strong dispersal barriers 12 In culture and relationship with humans editSiberian jays are reported to be fearless in human company and with repeated provision of food by humans in the same place may become tame enough to take food from the hand 16 This was especially the case when forestry workers used to regularly leave patches of food scraps in the forest or around campfires for the jays to take 16 The Siberian jay has now gained flagship status as a conservation concern both because of threats from modern forestry and because active territories are considered a sign of high quality biodiverse forest 18 Status editThe Siberian jay is evaluated as Least Concern by the IUCN because of the species exceptionally large range 1 Although the world population is declining the magnitude of this drop is not deemed to be sufficiently large to render the species Vulnerable 1 The world population is very large and estimated at 4 8 million mature individuals 1 Population declines have been reported to be strongest in the southernmost part of the range 1 References edit a b c d e f g h i BirdLife International 2016 Perisoreus infaustus IUCN Red List of Threatened Species 2016 e T22705775A87356809 doi 10 2305 IUCN UK 2016 3 RLTS T22705775A87356809 en Retrieved 12 November 2021 Siberian Jay Perisoreus infaustus Linnaeus 1758 Avibase Denis Lepage Retrieved 2 July 2017 Linnaeus Carl 1758 Systema Naturae per regna tria naturae secundum classes ordines genera species cum characteribus differentiis synonymis locis in Latin Vol 1 10th ed Holmiae Stockholm Laurentii Salvii p 107 Mayr Ernst Greenway James C Jr eds 1962 Check List of Birds of the World Vol 15 Cambridge Massachusetts Museum of Comparative Zoology p 238 Hartert Ernst 1903 Die Vogel der palaarktischen Fauna in German Vol 1 Berlin R Friedlander und Sohn p 34 Jobling James A 2010 The Helm Dictionary of Scientific Bird Names London Christopher Helm p 205 ISBN 978 1 4081 2501 4 Bonaparte Charles Lucien 1831 Saggio di una distribuzione metodica degli Animali Vertebrati di Carlo Luciano Bonaparte principe di Musignano Giornale Arcadico di Scienze Lettre ed Arti 49 3 77 42 a b Gill Frank Donsker David Rasmussen Pamela eds January 2021 Crows mudnesters birds of paradise IOC World Bird List Version 11 1 International Ornithologists Union Retrieved 16 May 2021 a b Jing Y Fang Y Strickland D Lu N Sun Y H 2009 Alloparenting in the rare Sichuan Jay Perisoreus internigrans The Condor 111 4 662 667 doi 10 1525 cond 2009 080114 a b c d e f g h Ekman Jan Sklepkovych Bohdan 1994 Conflict of interest between the sexes in Siberian jay winter flocks Animal Behaviour 48 2 485 487 doi 10 1006 anbe 1994 1266 Ekman Jan Ericson Per G P 2006 Out of Gondwanaland the evolutionary history of cooperative breeding and social behaviour among crows magpies jays and allies Proceedings of the Royal Society B Biological Sciences 273 1590 1117 1125 doi 10 1098 rspb 2005 3431 PMC 1560265 PMID 16600890 a b c Uimaniemi L Orell M Monkkonen M Huhta E Jokimaki J Lumme J 2000 Genetic diversity in the Siberian jay Perisoreus infaustus in fragmented old growth forests of Fennoscandia Ecography 23 6 669 677 doi 10 1111 j 1600 0587 2000 tb00310 x a b c d e f g h i j Ekman Jan Griesser Michael 2016 Siberian jays delayed dispersal in the absence of cooperative breeding In Walt Koenig Janis L Dickinson eds Cooperative breeding in vertebrates studies of ecology evolution and behavior Cambridge University Press pp 6 18 doi 10 1017 CBO9781107338357 002 ISBN 9781107043435 a b c d e Hogstad Olaf 2016 Hunting strategies by Siberian jays Perisoreus infaustus on wintering small rodents Ornis Norvegica 39 25 28 doi 10 15845 on v39i0 1031 a b c d e f g h i j k l Coombs Franklin 1978 The Crows a Study of the Corvids of Europe London B T Batsford OCLC 610890402 a b c d e f g h i j k l m n o p Blomgren Arne 1971 Studies of less familiar birds 162 Siberian Jay PDF British Birds 64 25 28 European Longevity Records Euring Retrieved 17 May 2021 a b c d e f g h i j Fabritius H 2010 Effective population size and the viability of the Siberian jay population of Suupohja Finland Master s thesis University of Helsinki a b Griesser Michael 2013 Do warning calls boost survival of signal recipients Evidence from a field experiment in a group living bird species Frontiers in Zoology 10 1 49 doi 10 1186 1742 9994 10 49 PMC 3751016 PMID 23941356 a b Griesser Michael Ekman Jan 2004 Nepotistic alarm calling in the Siberian jay Perisoreus infaustus Animal Behaviour 67 5 933 939 doi 10 1016 j anbehav 2003 09 005 a b Madge S 2009 Siberian Jay Perisoreus infaustus In del Hoyo J Elliot A Sargatal J Christie DA de Jauna E eds Handbook of the Birds of the World Alive Lynx Edicions Barcelona a b c Edenius Lars Meyer Carsten 2002 Activity budgets and microhabitat use in the Siberian Jay Perisoreus infaustus in managed and unmanaged forest PDF Ornis Fennica 79 26 33 a b Nystrand Magdalena 2006 Influence of age kinship and large scale habitat quality on local foraging choices of Siberian jays Behavioral Ecology 17 3 503 509 doi 10 1093 beheco arj055 a b c d e Griesser Michael 2003 Nepotistic vigilance behavior in Siberian jay parents Behavioral Ecology 14 2 246 250 doi 10 1093 beheco 14 2 246 a b c d e Griesser M Halvarsson P Drobniak S M Vila C 2015 Fine scale kin recognition in the absence of social familiarity in the Siberian jay a monogamous bird species PDF Molecular Ecology 24 22 5726 5738 doi 10 1111 mec 13420 PMID 26460512 a b c Ruth L 2016 Mate guarding in the Siberian jay Perisoreus infaustus Biology Independent Research Project Karlstads Universitet a b c d Lillandt B G Bensch S von Schantz T 2003 Family structure in the Siberian jay as revealed by microsatellite analyses The Condor 105 3 505 514 doi 10 1093 condor 105 3 505 a b c d Ekman J Eggers S Griesser M Tegelstrom H 2001 Queuing for preferred territories delayed dispersal of Siberian jays Journal of Animal Ecology 70 2 317 324 doi 10 1111 j 1365 2656 2001 00490 x a b c d e f g h Eggers S Griesser M Nystrand M Ekman J 2006 Predation risk induces changes in nest site selection and clutch size in the Siberian jay Proceedings of the Royal Society B Biological Sciences 273 1587 701 706 doi 10 1098 rspb 2005 3373 PMC 1560074 PMID 16608689 Harrison C 1975 A Field Guide to the Nests Eggs and Nestlings of British and European Birds London a b Eggers S 2002 Behaviour and life history responses to chick provisioning under the risk of nest predation PhD dissertation Uppsala University a b c Griesser M Nystrand M Eggers S Ekman J 2008 Social constraints limit dispersal and settlement decisions in a group living bird species Behavioral Ecology 19 2 317 324 doi 10 1093 beheco arm131 a b c Ekman Jan Griesser Michael 2002 Why offspring delay dispersal experimental evidence for a role of parental tolerance Proceedings of the Royal Society of London Series B Biological Sciences 269 1501 1709 1713 doi 10 1098 rspb 2002 2082 PMC 1691083 PMID 12204132 Ekman J Bylin A Tegelstrom H 1999 Increased lifetime reproductive success for Siberian Jay Perisoreus infaustus males with delayed dispersal Proceedings of the Royal Society B 266 1422 911 915 doi 10 1098 rspb 1999 0723 PMC 1689928 a b c d Ekman J Brodin A Bylin A Sklepkovych B 1996 Selfish long term benefits of hoarding in the Siberian jay Behavioral Ecology 7 2 140 144 doi 10 1093 beheco 7 2 140 a b Griesser M Halvarsson P Sahlman T Ekman J 2014 What are the strengths and limitations of direct and indirect assessment of dispersal Insights from a long term field study in a group living bird species PDF Behavioral Ecology and Sociobiology 68 3 485 497 doi 10 1007 s00265 013 1663 x Virkkala Raimo 1988 Foraging niches of foliage gleaning birds in the northernmost taiga in Finland PDF Ornis Fennica 65 104 113 a b c d Eggers S Griesser M Andersson T Ekman J 2005 Nest predation and habitat change interact to influence Siberian jay numbers Oikos 111 1 150 158 doi 10 1111 j 0030 1299 2005 13802 x Hagemeijer E J M Blair M J eds 1997 The EBCC Atlas of European breeding Birds their Distribution and Abundance London T and A D Poyser ISBN 978 0 85661 091 2 Griesser M Nystrand M Eggers S Ekman J 2007 Impact of forestry practices on fitness correlates and population productivity in an open nesting bird species PDF Conservation Biology 21 3 767 774 doi 10 1111 j 1523 1739 2007 00675 x PMID 17531054 Muukkonen P Angervuori A Virtanen T Kuparinen A Merila J 2012 Loss and fragmentation of Siberian jay Perisoreus infaustus habitats PDF Boreal Environment Research 17 59 71 Helle Pekka Jarvinen Olli 1986 Population trends of North Finnish land birds in relation to their habitat selection and changes in forest structure Oikos 46 1 107 115 doi 10 2307 3565386 JSTOR 3565386 External links editAudio recordings from Xeno canto An info card on the Siberian Jay at Birdlife org Retrieved from https en wikipedia org w index php title Siberian jay amp oldid 1217729030, wikipedia, wiki, book, books, library,

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